Diols Organic Syntheses procedures

Details for the large-scale synthesis of (R,R) 1,2-diphenyl-1,2-ethanediol by using the DHQD-CLB/NMO variation of catalytic AD have been published [47]. Under these conditions the crude diol is produced with 90% ee and upon crystallization, essentially enantiomerically pure diol is obtained in 75% yield. Subsequent improvements in the catalytic AD process now allow this dihydroxylation to be achieved with >99.8% ee (entry 20, Column 9) however, the Organic Synthesis procedure [47] is still an excellent choice for preparing large amounts of the... 

Conventional organic synthesis procedures are sometimes employed to prepare the simpler types of those molecules included here. Thus, (v/c-dihydroxyalkyl)phosphonic diesters are obtainable through the hydroxylation of the corresponding unsaturated acid esters using OSO4 and standard techniques. The isolation and purification of a diol may prove to be difficult because of possible intramolecular transesterification, sometimes accompanied by dehydration (reaction 12)" ... 

The generation of a quaternary carbon center is not a trivial undertaking in organic synthesis. Multiple synthetic steps are often required to generate a quaternary carbon. The high-yield formation of both alcohols and vicinal diols by a one-pot procedure with the concomitant formation of a quaternary carbon center was recently reported [19]. 

OXAZOLIDINECARBOXYLATE has previously been described in Volume 70 of Organic Sytheses. An alternative procedure for the preparation of this compound is presented in this volume along with its use in a dia-stereoselective addition reaction with 2-TRIMETHYLSILYLTH1AZOLE to provide a compound bearing a 2-amino-1,3-diol substructure that appears in a variety of natural products. The conversion of abundantly available isosorbide into OSO ISOPROPYLIDENE-l ti-DIANHYDRO-d-GLUCITOL provides a potentially useful carbohydrate-deri ved material for the use in complex tetrahydrofuran synthesis. Finally, asymmetric reduction of an a,j9-unsaturated acylstannane with (R)-BINAL provides access to (S,E)-l-(METHOXYMETHOXY)-l-TRIBUTYLSTANNYL-2-BUTENE, an a-alkoxy allylstannane that has been used in enantioselective vicinal diol synthesis amongst other transformations. 

There has been considerable research into the electrolytic reduction of aromatic carboxylic acids to the corresponding aldehydes. A general procedure has been described in which key elements are the use of the ammonium salt of the acid, careful control of the pH and the presence of an organic phase (benzene) to extract the aldehyde and thus minimize overreduction. The method appears to work best for relatively acidic substrates for example, salicylaldehyde was obtained in 80% yield. Danish workers have shown that, under acidic conditions, controlled electrolytic reductions are possible for certain pyridine-, imidazole- and thiazole-carboxylic acids. In these cases, it is thought that the product aldehydes are protected by geminal diol formation. A chemical method which is closely related to electrolysis is the use of sodium amalgam as reductant. Although not widely used, it was successfully employed in the synthesis of a fluorinated salicylaldehyde. ... 

---